Distributing communication of a data stream among multiple devices

ABSTRACT

Methods, apparatus and articles of manufacture for distributing communication of a data stream among multiple devices are disclosed. Example methods disclosed herein include receiving, at a first device, a sharing code from a second device, the sharing code to associate multiple devices with a shared connection to be established to distribute communication of a complete data stream among the multiple devices, the multiple devices including the first device. Disclosed example methods also include transmitting a request including the sharing code from the first device to a distribution system to establish a data connection via which the first device is to receive a first partial data stream corresponding to a portion of the complete data stream from the distribution system. Disclosed example methods further include forwarding the first partial data stream from the first device to the second device.

RELATED APPLICATION(S)

This patent arises from a continuation of U.S. patent application Ser.No. 13/563,225 (now U.S. Pat. No. 9,491,093), which is entitled“DISTRIBUTING COMMUNICATION OF A DATA STREAM AMONG MULTIPLE DEVICES,”and which was filed on Jul. 31, 2012. U.S. patent application Ser. No.13/563,225 is hereby incorporated by reference in its entirety.

FIELD OF THE DISCLOSURE

This disclosure relates generally to data communications and, moreparticularly, to distributing communication of a data stream amongmultiple devices.

BACKGROUND

Consumers are becoming accustomed to near ubiquitous access toInternet-based and web-based services and applications. In the past,data intensive applications, such as steaming video, on-demand video,video conferencing, etc., were limited to devices, such as personalcomputers, set-top boxes, stand-alone video conferencing systems, etc.,having dedicated, high-speed (e.g., broadband) data connections providedby an Internet service provider (ISP). Today, consumers have access to aplethora of electronic devices, including smartphones, tablet computers,personal data devices, personal digital assistants, etc., that supportInternet connectivity, and may have sufficient processing power tosupport at least some media-rich applications. However, while a consumermay own or have access to a number of such electronic devices, the databandwidth capabilities of each individual device may be limited suchthat none of the consumer's devices, on its own, can support the datatransfer speeds associated with a data intensive application theconsumer wishes to access.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1 is block diagram of an example communication system capable ofdistributing communication of a data stream among multiple exampledevices as disclosed herein.

FIG. 2 is block diagram of an example distribution server that may beused to implement the example communication system of FIG. 1.

FIG. 3 is block diagram of an example connection manager that may beused to implement the example communication system of FIG. 1.

FIG. 4 is block diagram of an example primary device that may be used inthe example communication system of FIG. 1.

FIG. 5 is block diagram of an example secondary device that may be usedin the example communication system of FIG. 1.

FIG. 6 is a flowchart representative of example machine readableinstructions that may be executed to implement the example communicationsystem of FIG. 1.

FIG. 7 is a flowchart representative of example machine readableinstructions that may be executed to implement the example primarydevice of FIG. 4.

FIG. 8 is a flowchart representative of example machine readableinstructions that may be executed to implement the example secondarydevice of FIG. 5.

FIG. 9 is a flowchart representative of example machine readableinstructions that may be executed to implement the example distributionserver of FIG. 2 and/or the example connection manager of FIG. 3.

FIG. 10 is a block diagram of an example processing system that mayexecute the example machine readable instructions of FIGS. 6-8 and/or 9to implement the example communication system of FIG. 1, the exampledistribution server of FIG. 2, the example connection manager of FIG. 3,the example primary device of FIG. 4 and/or the example secondary deviceof FIG. 5.

Wherever possible, the same reference numbers will be used throughoutthe drawing(s) and accompanying written description to refer to the sameor like elements, parts, etc.

DETAILED DESCRIPTION

Methods, apparatus and articles of manufacture (e.g., storage media) fordistributing communication of a data stream among multiple devices aredisclosed herein. Example methods disclosed herein to distributecommunication of a first data stream among multiple devices includereceiving a request from an example primary device to establish a sharedconnection to distribute the communication of the first data streamamong a group of devices. In some such examples, the group of devicesincludes the primary device and a group of secondary devices. Suchexample methods also include providing, in response to the request,network addresses to the primary device to be used to establishrespective data connections with the group of devices. Such examplemethods further include splitting the first data stream into a group ofpartial data streams to be communicated respectively to the group ofdevices via the respective data connections. In such examples, thepartial data streams, when aggregated, form the first data stream.

In some such examples, a number of network addresses provided to theprimary device corresponds to a number of secondary devices indicated inthe request as being included in the shared connection. In suchexamples, the primary device is to distribute the network addresses tothe group of secondary devices to be used to establish respective dataconnections with the group of secondary devices.

Additionally or alternatively, some such example methods further includeestablishing a primary data connection with the primary device inresponse to receiving the request. Such example methods also includeestablishing respective secondary data connections with the group ofsecondary devices in response to receiving communications from the groupof secondary devices at the network addresses provided to the primarydevice. In some examples, each of the group of secondary devices isassociated with a respective different network address that was providedto the primary device.

Additionally or alternatively, some such example methods further includedetermining first device capability information for the primary device,and establishing the primary data connection with the primary devicebased on the first device capability information. Such example methodsalso include determining respective device capability information foreach of the group of secondary devices, and establishing the respectivesecondary data connections with the group of secondary devices based onthe respective device capability information determined for each of thegroup of secondary devices. In some such examples, determining the firstdevice capability information involves processing a first ping messagesent to the primary device, and determining the respective devicecapability information for each of the group of secondary devicesinvolves processing respective ping messages sent to the plurality ofsecondary devices. Additionally or alternatively, in some such examples,establishing the primary data connection with the primary deviceincludes associating at least one of a first bandwidth limit or a firstdata rate limit with the primary data connection based on the firstdevice capability information. Additionally or alternatively, in somesuch examples, establishing the respective secondary data connectionswith the group of secondary devices includes associating at least one ofa respective bandwidth limit or a respective data rate limit with eachof the respective secondary data connections based on the respectivedevice capability information determined for each of the group ofsecondary devices.

Additionally or alternatively, some such example methods further includedetecting a change in status of the shared connection. Such examplemethods can also include adjusting the splitting of the first datastream to account for the change in status.

Further example methods, apparatus and articles of manufacture (e.g.,storage media) for distributing communication of a data stream amongmultiple devices are described in greater detail below.

As noted above, a consumer may have access to multiple electronicdevices that support Internet connectivity, but none of these devicesmay have sufficient data bandwidth capability, on its own, to supportthe data intensive applications the consumer may wish to access. Forexample, a lack of sufficient data bandwidth may prevent a consumer fromusing a given one of her electronic devices to view a streaming video,participate in a video conference, etc., or may at least degrade theconsumer's experience when accessing such applications. In manycircumstances, the consumer has access to a number of electronic deviceshaving a combined bandwidth that would be sufficient to support thedesired data intensive application. Thus, while the total bandwidthavailable to the consumer would be sufficient, the distribution of thisbandwidth among multiple, individual devices (e.g., which may be ofdifferent types) has, in the past, prevented this available bandwidthfrom being used to its full potential.

Example methods, apparatus and articles of manufacture disclosed hereincan overcome at least some of these prior limitations, and enable thebandwidth from multiple devices to be combined. For example, suchdisclosed example methods, apparatus and articles of manufacturedistribute communication of a data stream (e.g., such as a high-speeddata stream corresponding to a streamlining video application, a videoconferencing application, etc.) among the multiple devices, therebyenabling the limited bandwidth of each device to be combined to realizea data connection (referred to herein as a shared connection) having ahigher overall bandwidth. Prior techniques for combining the bandwidthof separate communication links, such as link bonding or aggregation,can be limited in that they are restricted to use with fixed, or static,communication links implemented using the same technology and/orprovided by the same service provider, and/or require the communicationlinks being combined to terminate at the same communication endpoint.

Unlike such prior techniques, example methods, apparatus and articles ofmanufacture disclosed herein enable distribution of the communication ofa data stream among multiple, different endpoints (e.g., electronicdevices), which may be the same or different and which may receiveservice (e.g., Internet service) from the same or different providers.Also, example methods, apparatus and articles of manufacture disclosedherein support distribution of the data stream among different dataconnections in accordance with the different device capabilities of thedevices with which the data connections are established. Furthermore,example methods, apparatus and articles of manufacture disclosed hereinsupport flexible combining of device bandwidth such that, for example,devices may be added to and/or removed from the shared connection whilethe data stream is still being communication. Further aspects of thedisclosed example methods, apparatus and articles of manufacture aredescribed in greater detail below.

Turning to the figures, a block diagram of an example communicationsystem 100 capable of distributing communication of a data stream amongmultiple example devices as disclosed herein is illustrated in FIG. 1.The communication system 100 includes multiple example user devices105A-E in communication with one or more example service providernetworks 110. The service provider network(s) 110 can correspond to anytype of service provider's network, such as a mobile service providenetwork, a broadband service provider network, a cable service providernetwork, a satellite service provider network, an Internet serviceprovider (ISP) network, etc., capable of providing access to theInternet and/or any service-oriented and/or content delivery network. Inthe example communication system 100 of FIG. 1, Internet service isprovided to each of the multiple user devices 105A-E by the same ordifferent service provider network(s) 110. Furthermore, the user devices105A-E may have different device capabilities such that, for example,some or all of the user devices 105A-E have different respectivebandwidth or data rate limits for data received from and/or transmittedto the service provider network 110.

Although the user devices 105A-E are depicted as mobile phones in FIG.1, the user devices 105A-E are not limited thereto. For example, theuser devices 105A-E can each be any device that is capable of accessingthe service provider(s) 110, which in turn provides access to theInternet and/or any other type(s) of content delivery and/orservice-oriented network(s). Each user device 105A-E is also able toexchange data with other external device(s), such as via tetheringand/or any external data connection (such as a Wi-Fi connection, aBluetooth connection, a universal serial bus (USB) connection, a dockingconnection, etc.). As such, the user devices 105A-E can be implementedby, for example, mobile phones (such as smartphones, cellular phones,3G, 4G or long term evolution (LTE) wireless devices, etc.), wirelessaccess points (such as Wi-Fi devices, Bluetooth devices, aircards,etc.), personal data devices (such as personal digital assistants(PDAs), e-readers, etc.), broadband modems (such as DSL modems, cablemodems, satellite modems, etc.) and/or any other type(s) of electronicdevices or combinations thereof.

In the illustrated example of FIG. 1, the service provider network(s)110 provide the user devices 105A-E with access to one or more exampledata sources 115. The data sources(s) 115 include, for example, one ormore streaming media sources (e.g., such as streaming services offeredby Netflix®, Hulu®, etc.), one or more on-demand media download sources(e.g., such as Apple iTunes®), one or more video conferencing services,etc. The data source(s) 115 can also include other user devices (notshown) capable of uploading content (e.g., such as video chat content)that is able to be received by the user devices 105A-E.

The example communication system 100 of FIG. 1 further includes anexample distribution system 120 that enables the communication of aparticular data stream from the data sources(s) 115 to be distributedamong the multiple user devices 105A-E. For example, the distributionsystem 120 may be used to distribute portions of a data stream, which isbeing communicated from a data source 115 to one of the user devices105A-E, such as the user device 105A, to some or all of the multipleuser devices 105A-E. As described in greater detail below, the partialdata streams received by some or all of the user devices 105A-E are thenaggregated to form the original data stream, which may be processed bythe user device 105A (e.g., for presentation by the user device 105A)and/or forwarded to an example output device 125 (e.g., for presentationby the output device 125). In this way, the individual bandwidths and/ordata transmission capacity limits of each of the user devices 105A-E canbe combined to yield an aggregated bandwidth and/or data transmissioncapacity capable of carrying a data stream that would not have beensupported by the user devices 105A-E otherwise. The output device 125 ofthe illustrated example can be implemented by any type of device capableof processing, presenting and/or otherwise using a data stream, such asa television, a set-top box, a personal computer, etc., and/or any othertype of user device, such as device similar to the user devices 105A-Edescribed above.

To support distributing communication of a data stream among themultiple user devices 105A-E as disclosed herein, the distributionsystem 120 of the illustrated example further includes an exampledistribution server 130 and an example connection manager 135. Asdescribed in greater detail below, the distribution server 130 isresponsible for splitting a complete data stream being provided by adata source 115 into multiple partial data stream to be communicated tothe respective user devices 105A-E. As described in greater detailbelow, the connection manager 135 is responsible for establishing,monitoring and otherwise managing the data connections with the userdevices 105A-E that collectively form the shared connection via whichthe original data stream is communicated as a group of partial datastream to the user devices 105A-E.

In the example communication system 100 of FIG. 1, the distributionsystem 120, which includes the distribution server 130 and theconnection manager 135, may or may not be included in the serviceprovider network(s) 110. For example, the distribution system 120 may beimplemented by a content delivery network or other service-orientednetwork connecting the data source(s) 115 with the service providernetwork(s) 110. Because the distribution system 120 may be implementedoutside of the service provider network(s) 110, the connection manager135 may not be able to rely on the service provider network(s) 110 toestablish the data connections with the secondary devices 105B-E amongwhich the data stream provided by the target data source 115 is to bedistributed. For example, some of the secondary devices 105B-E mayreceive service from different service provider network(s) 110, and theservice provider network(s) 110 may act as pass-through for thecommunication messages associated with establishing the data connectionsfor data stream distribution. As such, in some examples, the serviceprovider network(s) 110 in the communication system 100 of FIG. 1 routethe shared connection requests (described in greater detail below) tothe separate distribution system 120 without establishing the dataconnections disclosed herein.

An example of distributing communication of a data stream among themultiple user devices 105A-E in the context of the communication system100 is now described. Consider, for example, a scenario in which a userendeavors to use the user device 105A to access a data source 115 tobegin data streaming or downloading using data stream distribution asdisclosed herein. In such examples, the user device 105A is referred toherein as a primary device and is responsible for establishing theshared connection between the user devices 105A-E, managing the sharedconnection, selecting the target data source 115, etc. The other userdevices 105B-E are referred to herein as secondary devices to beincluded in the shared connection that is to convey the data stream fromthe selected data source 115 to the user devices 105A-E.

In such examples, the user uses the primary device 105A to establishlocal communication links with one or more of the secondary user devices105B-E. For convenience, and without loss of generality, it is assumedthat all of the user devices 105A-E are to be included in the sharedconnection. For example, the user devices 105A-E can establish an ad-hocnetwork, tethering connections and/or other local communication linksvia any appropriate technology, such as Wi-Fi connections, Bluetoothconnections, USB connections, a docking connections, etc. In theillustrated example, the primary device 105A uses the localcommunication links to determine the number of secondary devices 105B-Ethat are to be included in the shared connection associated with aparticular target data stream. The primary device 105A then sends ashared connection request, for receipt by the distribution system 120,which requests that a shared connection be established to distribute adata stream from a target data source 115. In the illustrated example,the shared connection request identifies the target data source 115 andincludes the number of secondary user devices 105B-E to be included inthe shared connection.

In the example communication system 100 of FIG. 1, the distributionsystem 120 is not implemented in the service provider network(s) 110.Accordingly, the receiving service provider network 110 forwards theshared connection request to the distribution system 120 and, inparticular, the connection manager 135, to enable the shared connectionamong the user devices 105A-E to be established. In the illustratedexample, the distribution system 120 in combination with the userdevices 105A-E implement functionality to enable respective dataconnections (also referred to herein as secondary data connections) tobe established with the secondary devices 105B-E. (It is assumed that adata connection, also referred to herein as a primary data connection,is already established with the primary device 105A as the request isreceived as a data communication from the primary device 105A.) Forexample, the distribution system 120 in combination with the userdevices 105A-E can implement functionality to enable the user devices105A-E to initiate establishment of their respective data connectionsvia which data streaming is to be distributed. For example, thedistribution system 120 can provide a set of network addresses (e.g.,uniform resource identifiers (URIs), IP addresses, etc.) and/or asharing code to be used by the user devices 105A-E to establish the dataconnections for use in distributing a data stream, and to associate theuser devices 105A-E with a particular (e.g., unique) group of devicesthat is to receive a particular data stream.

For example, in the communication system 100 of FIG. 1, the serviceprovider network 110 serving the primary device 105A receives the sharedconnection request from the primary device 105A and forwards it to theconnection manager 135. In response to receiving the request, theconnection manager 135 returns a set of network addresses, such as IPaddresses, URIs, etc., to the primary device 105A to be used by thesecond devices 105B-E to establish respective data connections (alsoreferred to herein as secondary data connections) with the distributionssystem 120. (It is assumed that the primary data connection is alreadyestablished with the primary device 105A when the request is received bythe distribution system 120 from the primary device 105A.) For example,the connection manager 135 may return a number of network addressescorresponding to the number of secondary devices indicated in the sharedconnection request such that each secondary device 105B-E can beassociated with a different respective network address. In response toreceiving the network addresses from the connection manager 135, theprimary device 105A of the illustrated example forwards the networkaddresses to the secondary devices 105B-E via the local communicationlinks (e.g., with each secondary device receiving a different networkaddress). Each secondary device 105B-E then sends a request to thenetwork address it received from the primary device 105A, which isreceived by the connection manager 135 of the distribution system 120.Because the connection manager 135 knows which network addresses itassigned to a particular shared connection request, the connectionmanager 135 can associate the secondary devices 105B-E with a particularshared connection request based on the network addresses used by thesecondary devices 105B-E to contact the distribution system 120. Thus,in response to receiving a communication from a particular secondarydevice 105B-E at the provided network address, the connection manager135 can establish a data connection with the particular secondary device105B-E and associate it with the proper shared connection request.

Additionally or alternatively, in response to receiving the sharedconnection request from the primary device 105A, the connection manager135 may return a sharing code, or a shared connection code, such as aunique number or alphanumeric sequence, to be associated with thatparticular shared connection request. In response to receiving thesharing code from the connection manager 135, the primary device 105A ofthe illustrated example forwards the sharing code to the secondarydevices 105B-E via the local communication links. The secondary devices105B-E can then include this code in a request sent to the distributionsystem 120 to cause the connection manager 135 to associate, based onthe sharing code, the secondary devices 105B-E with the particularshared connection requested by the primary device 105A. In someexamples, the sharing code can be used with or without a group ofnetwork addresses also being provided by the connection manager 135. Forexample, user devices, such as the devices 105A-E, could be configuredto use just a single network address (or relatively small number ofnetwork addresses) to contact the distribution system 120 with a sharingrequest including their assigned sharing code. In such examples, theconnection manager 135 can rely on the sharing code to group userdevices into different requested shared connections, and can thenestablish the data connections with the user devices accordingly.

In some examples, some or all of the user devices 105A-E eachindividually send separate, initial shared connection requests to thedistribution system 120 before being associated with a particular sharedconnection. In such examples, the connection manager 135 may assign andreturn a respective sharing code to each device. The user devices 105A-Emay then exchange their respective sharing codes amongst each other(e.g., via the local communication links established among the devices)to thereby identify which user devices 105A-E are to be included in theshared connection. In such examples, one of the user devices 105A-E,such as the primary user device 105A, then sends a second, orsupplemental, shared connection request to the distribution system 120,which identifies (e.g., using the assigned sharing codes) the userdevices 105A-E to be included in the shared connection, and the targetdata source 115.

Furthermore, in some such examples, one or more of the user devices105A-E may include location information in the individual, initialshared connection request(s) sent to the distribution system 120. Insuch examples, the connection manager 135 may identify groups of userdevices 105A-E that are geographically co-located (e.g., within aspecified or configured geographical distance of each other) as likelycandidates for inclusion in a shared connection. Accordingly, theconnection manager 135 may then assign a single sharing code, or givenranges of sharing codes, to user devices 105A-E that are geographicallyco-located. Then, when the user devices 105A-E exchange sharing codesamongst each other, the values of the sharing codes can be evaluated(e.g., to identify which user devices have codes that are the same as,or within a range of, the sharing code assigned to a receiving userdevice) to determine which other user devices 105A-E are within rangeand may be included in a shared connection.

In some examples, the connection manager 135 further establishes thedata connections with the devices 105A-E by associating respective datatransmission characteristic(s) with each of the data connections. In theillustrate example, the data transmission characteristic(s) aredetermined by the connection manager 135 based on the device capabilityinformation obtained for the user devices 105A-E. For example, theconnection manager 135 can allocate different bandwidth and/or data ratelimits to some or all of the data connections based on the devicecapability information for each of the devices 105A-E.

In the illustrated example, the connection manager 135 activelydetermines the device capability information for the user devices 105A-E(e.g., because the connection manager 135 may not be able to rely onreceiving such information from the service provider network(s) 110).For example, the connection manager 135 may exchange communicationmessages, such a network ping messages, with the primary device 105A todetermine device capability information, such as bandwidth and/or datarate capabilities, network latencies, etc. Similarly, the connectionmanager 135 may exchange communication messages, such a network pingmessages, with each of the secondary devices 105B-E included in a sharedconnection request to determine respective device capability informationfor the secondary devices 105B-E, such as bandwidth and/or data ratecapabilities, network latencies, etc. Then, as described above, theconnection manager 135 can associate respective data transmissioncharacteristic(s) with the data connections established with the userdevices 105A-E, with the data transmission characteristic(s) being basedon the determined device capability information.

After establishing the data connections with the respective devices105A-E and determining their respective data transmissioncharacteristics, the connection manager 135 then initiates the datastream from target data source 115 using the target data sourceidentification information included in the shared connection request.The connection manager 135 also invokes the distribution server 130 tobegin splitting of the complete data stream among the respective dataconnections with the user devices 105A-E.

In the illustrated example, the distribution server 130 receives thecomplete data stream from the target data source 115 corresponding tothe target data source identification information included in the sharedconnection request. The distribution server 130 splits the complete datastream into partial data streams to be communicated to the user devices105A-E using the communication paths established by the connectionmanager 135 and the service provider network 110. In some examples, thedistribution server 130 generates the partial data streams havingdifferent data transmission characteristics, such as different bandwidthlimits and/or data rate limits, according to the respective datatransmission characteristics associated with the communication pathsestablished with the user devices 105A-E. In some examples, thedistribution server 130 may also perform transcoding to change/modifyone or more data stream characteristics when splitting the complete datastream into the partial data streams, as described in greater detailbelow.

In the illustrated example, the user devices 105A-E receive theirrespective partial bit streams from the distribution server 130 via theestablished communication paths. The received partial bits streams arethen aggregated (e.g., possibly after reordering to account fordifferent data packet arrival times at the different user devices105A-E) to form the complete data stream being provided by the targetdata source 115. Any appropriate aggregation technique can be employedin the communication system 100 to aggregate the partial data streamsreceived by the user devices 105A-E. For example, as illustrated in theexample of FIG. 1, the secondary devices 105B-E can forward theirrespective received partial data streams to the primary device 105A viathe local communication links previously established (as describedabove) between the user devices 105A-E. In such examples, the primarydevice 105A aggregates the partial data streams received from thesecondary devices 105B-E with its own received partial data stream toform the complete data stream being provided by the target data source115. The primary device 105A can the process/present the complete datastream itself, or convey the complete data stream to the output device125 for processing/presentation.

Additionally or alternatively, in some examples, the user devices 105A-Esupport hierarchical aggregation of the partial data streams to form thecomplete data stream provided by the target data source 115. In suchexamples, subsets of the user devices 105A-E work cooperatively toperform a first level of data stream aggregation (e.g., which can beperformed in parallel among the different device subsets). For example,the secondary device 105B could perform aggregation of the partial datastreams received by the secondary devices 105B-C, and the secondarydevice 105D could perform aggregation of the partial data streamsreceived by the secondary devices 105D-E. The resulting aggregatedstreams from the first level of aggregation can then be provided toanother device, such as the primary device 105A, to perform a next levelof data stream aggregation. Additional levels of aggregation can beimplemented, as appropriate.

Additionally or alternatively, in some examples, the user devices 105A-Eprovide their respective received partial data streams to the outputdevice 125, which is responsible for performing the data streamaggregation.

In some examples, the connection manager 135 and/or the primary device105 of the communication system 100 monitor the status of the sharedconnection established between the distribution system and the userdevices 105A-E to determine whether to modify distribution of thecomplete data stream among the multiple devices 105A-E. For example, ifone or more of the user devices 105A-E is/are no longer available (e.g.,due to leaving the operating area, being turned-off, etc.), theconnection manager 135 and/or the primary device 105 can detect such achange and cause the complete data stream to be distributed just overthe remaining user devices 105A-E. Additionally or alternatively, a newuser device (not shown) may become available (e.g., by entering theoperating area, by being turned on, etc.) for inclusion in the group ofdevices 105A-E among which the complete data stream is to bedistributed. In some examples, the connection manager 135 and/or theprimary device 105 can detect such a change and cause the complete datastream to be distributed over the new group user devices 105A-E. Suchmonitoring capabilities enables the communication system 100 to continueproviding the complete data stream from the target data source to theuser devices 105A-E even as the composition of the user devices 105A-Echanges.

Although five user devices 105A-E are illustrated in the example of FIG.1, the communication system 100 can support distributing thecommunication of a data stream among any number of user devices 105A-E.The communication system 100 can also support any number and/or type(s)of data sources 115 and output devices 125. Furthermore, thecommunication system 100 can include any number of service providernetworks 110 providing the user devices 105A-E with access to theInternet and/or any other content delivery and/or service orientednetwork(s). Moreover, although one distribution system 120 isillustrated in the example of FIG. 1, the communication system 100 cansupport any number of distribution systems 120 to distributecommunication of data streams among multiple devices as disclosedherein. Furthermore, although the distribution system 120 is illustratedas being implemented outside of the service provider network(s) 110 inthe example of FIG. 1, in other examples the distribution system 120 maybe implemented by/in a service provider network 110. In such examples,the distribution system 120 may obtain, for example, the above-mentionedlocation information and/or device capability information for one ormore of the user devices 105A-E directly from the service providernetwork 110 implementing the distribution system 120, rather thaninteracting with the user devices 105A-E to obtain such information.

A block diagram depicting an example implementation of the distributionserver 130 of FIG. 1 is illustrated in FIG. 2. The example distributionserver 130 of FIG. 2 includes an example data receiver 405 to receivedata stream(s) from one or more data sources, such as the data source(s)115. The example distribution server 130 of FIG. 2 also includes anexample stream splitter 410 to split an incoming data stream from a datasource into a group of partial streams to be distributed to userdevices, such as the user devices 105A-E, via established dataconnections. In some examples, the stream splitter 410 is configured(e.g., by the connection manager 135) with respective data transmissioncharacteristics for each of the data connections and, thus, for each ofthe partial data streams into which the incoming data stream is to besplit. For example, each data connection and associated partial datastream can be associated with a respective bandwidth limit, data ratelimit, etc., tailored to the device capabilities of the particular userdevice that is to receive that partial data stream. Accordingly, in someexamples, the stream splitter 410 may split the incoming data streaminto partial data streams having different data transmissioncharacteristics, whereas in other examples, the stream splitter 410 maysplit the incoming data stream into partial data streams having similar,or the same, data transmission characteristics.

In some examples, the example distribution server 130 of FIG. 2 furtherincludes an example transcoder 415 to transcode the data as it is beingsplit from the incoming data stream into the partial data streams. Thetranscoder 415 performs transcoding to modify the characteristics of thedata payload and/or control information included in the partial datastreams generated by the stream splitter 410 from the incoming datastream. For example, based on the device capabilities of a particularuser device associated with a particular data stream, the transcoder 415may be used to modify the partial data stream to change the block sizeof the data payload, perform data interpolation on the data payload,re-encode control information included in the partial data stream, etc.,to conform the partial data stream with one or more communicationprotocols supported by the user device. Accordingly, the transcoder 415can support any number and/or type(s) of transcoding algorithms tailoredto the expected device capabilities of user devices that are to receivethe partial data streams generated by the distribution server 130.

A block diagram depicting an example implementation of the connectionmanager 135 of FIG. 1 is illustrated in FIG. 3. The example connectionmanager 135 of FIG. 3 includes an example shared connection requestreceiver 505 to receive shared connection requests from user devices,such as the primary user device 105A. As described above, a sharedconnection request includes, for example, data source identificationinformation identifying a target data source, such as a data source 115,from which the primary user device 105A is requesting that a data streambe provided. In some examples, the shared connection request can includeinformation indicating the number of secondary user devices (or thenumber of user devices in total) that are to be included in the sharedconnection among which the data stream from the identified target sourceis to be distributed, as described above.

The example connection manager 135 of FIG. 3 also includes an exampleshared connection allocator 510 to allocate data connections for theuser devices to be included in a shared connection established inresponse to a shared connection request received by the sharedconnection request receiver 505. In some examples, the shared connectionallocator 510 processes the shared connection request received by theshared connection request receiver 505 to determine a number of userdevices to be included in the shared connection being requested (e.g.,by evaluating the number of secondary user devices or total user devicesindicated in the shared connection request). The shared connectionallocator 510 then allocates a number of data connections correspondingto the number of user devices. The shared connection allocator 510 alsogenerates a response to the shared connection request containing, forexample, a number of network addresses (e.g., IP addresses, URIs, etc.)to be used by the user devices as destination addresses of thedistribution system 120 that are to be contacted to establish the dataconnections for receiving the partial data streams corresponding to thetarget data source identified in the shared connection request.Additionally or alternatively, the shared connection allocator 510 caninclude a sharing code or other identifier to be used by the userdevices when contacting the distribution system 120 to establish thedata connections for receiving the partial data streams corresponding tothe target data source identified in the shared connection request. Insuch examples, the sharing code is used by the shared connectionallocator 510 to associated user devices with particular sharedconnection requests.

In some examples, the shared connection allocator 510 activelydetermines device capability information for the user devices to beincluded in the requested shared connection. For example, the sharedconnection allocator 510 may exchange communication messages, such asnetwork ping messages, with a primary device in response to receivingthe shared connection request to determine device capabilityinformation, such as bandwidth and/or data rate capabilities, networklatencies, etc. Similarly, in response to receiving a message from asecondary device at a provided network address and/or including anappropriate sharing code, the shared connection allocator 510 mayexchange communication messages, such as network ping messages, with thesecondary devices to determine respective device capability information,such as bandwidth and/or data rate capabilities, network latencies,etc., for the secondary device. The shared connection allocator 510 thenuses this device capability information to determine data transmissioncharacteristics to be associated with the data connection establishedwith the user devices, as described above.

The example connection manager 135 of FIG. 3 further includes an exampledata stream initiator 515 to initiate a data stream from the target datasource identified in the shared connection request received by theshared connection request receiver 505. For example, the data streaminitiator 515 can initiate data streaming or another type of datadownload from the target data source, and indicate that the destinationof the stream is a network address that is associated with thedistribution system 120 and is further associated with the particularshared connection that was established in response to the receivedshared connection request. In such examples, the distribution system 120knows that a data stream received at an address associated with aparticular shared connection is to be distributed into partial datastreams by the distribution server 130 as disclosed herein.

In some examples, the example connection manager 135 of FIG. 3 includesan example shared connection monitor 520 to monitor the status of sharedconnections being used to distribute the communication of data streamsamong multiple user devices. For example, to monitor a shared connectionassociated with the user devices 105A-E, the shared connection monitor520 can monitor for status update messages received from the primaryuser device 105A to indicate that the composition of the group of userdevices 105A-E associated with the shared connection has changed (e.g.,because user device(s) have entered or left the group). Additionally oralternatively, in some examples the shared connection monitor 520 canmonitor that status of partial data streams being communicated to thegroup of user devices 105A-E associated with the shared connection todetermine whether one or more of the streams has stalled (e.g., becauseacknowledgment(s) have not been received from one or more of the userdevices 105A-E). In the illustrated example, in response to detecting achange in status of a shared connection, the shared connection monitor520 notifies the shared connection allocator 510 to cause the sharedconnections with the user devices 105A-E to be updated accordingly(e.g., to add/delete user connections, to adjust the allocation of datato the different partial data streams, etc.).

A block diagram depicting an example implementation of the primary userdevice 105A of FIG. 1 is illustrated in FIG. 4. The example primary userdevice 105A of FIG. 4 includes an example wide area transceiver 605 thatimplements any number and/or type(s) of wireline and/or wirelesscommunication interfaces, protocols, etc., to communicate with one ormore of service provider networks, such as the service providernetwork(s) 110. The primary user device 105A of FIG. 4 also includes anexample local area transceiver 610 that implements any number and/ortype(s) of wireline and/or wireless communication interfaces, protocols,etc., to implement one or more local data connections with one or moresecondary devices, such as the secondary devices 105B-E. For example,the local area transceiver 610 can implement local data connections withother secondary devices via an ad-hoc network, tethering and/or anyexternal data connection (such as a Wi-Fi connection, a Bluetoothconnection, a universal serial bus (USB) connection, a dockingconnection, etc.).

The example primary user device 105A of FIG. 4 further includes anexample primary device graphical user interface (GUI) 615 to provide aninterface by which a user may invoke, monitor, modify, etc., a sharedconnection for distributing a data stream among multiple user devices,as disclosed herein. For example, the primary device GUI 615 can beimplemented by an Internet browser, a wireless application protocol(WAP) browser, a JAVA application, etc. In some examples, the primarydevice GUI 615 provides an interface to enable a user to select a targetdata source, such as one of the target data source(s) 115, that is toprovide the data stream whose communication is to be distributed amongthe multiple user devices via the shared connection. In some examples,the primary device GUI 615 also provides an interface to enable a userto select and/or otherwise identify the secondary devices, such as thesecondary devices 105B-E, to be included with the primary user device105A in the shared connection. For example, the primary device GUI 615can cause the primary user device 105A to initiate any type of automateddiscovery process to detect the secondary device(s) 105B-E that arewithin communication range of the primary user device 105A. Additionallyor alternatively, the primary device GUI 615 may implement an interfaceto enable the user to manually enter secondary device identificationinformation, such as phone number(s), URI(s), etc., for the secondarydevice(s) 105B-E to be included with the primary device 105A in theshared connection. Furthermore, in some examples, the primary device GUI615 provides an interface to enable the user to initiate establishmentof the shared connection via which communication of a data stream is tobe distributed among the multiple user devices. Also, in some examples,the primary device GUI 615 enables a user to specify whether locationinformation for the primary device 105A is to be included in requests toestablish such shared connections.

The example primary user device 105A of FIG. 4 further includes anexample secondary device identifier 620 to identify the secondarydevices, such as the secondary devices 105B-E, to be included with theprimary user device 105A in the shared connection. For example, theprimary device GUI 615 can initiate any type of automated discoveryprocess to detect (e.g., via communication links established by thelocal area transceiver 610) the secondary device(s) 105B-E that arewithin communication range of the primary user device 105A. Additionallyor alternatively, the primary device GUI 615 may receive secondarydevice identification information, such as phone number(s), URI(s),etc., entered manually via the primary device GUI 615 for the secondarydevice(s) 105B-E to be included with the primary device 105A in theshared connection.

The example primary user device 105A of FIG. 4 also includes an exampleshared connection requestor 625 to generate and send a shared connectionrequest, as described above, to a distribution system, such as thedistribution system 120, to request establishment of a shared connectionvia which communication of a data stream from an identified target datasource is to be distributed. For example, the shared connectionrequestor 625 can generate a shared connection request message includingtarget source identification information (e.g., specified via theprimary device GUI 615) specifying the target data source 115 from whichthe data stream to be distributed is to be provided. Additionally oralternatively, in some examples, the shared connection request messagegenerated by the shared connection requestor 625 can indicate the numberof secondary devices 105B-E to be included in the requested sharedconnection.

The example primary user device 105A of FIG. 4 further includes anexample stream aggregator 630 to reorder and/or otherwise aggregatepartial data streams received from other user devices 105B-E to form thecomplete data stream being provided by the target data source 115identified in the shared connection request generated and sent to thedistribution system 120 via the shared connection requestor 625. Forexample, the stream aggregator 630 of the illustrated example canreceive, via the local communication links established using the localarea transceiver 610, one or more of the partial data streams from thesecondary user devices 105B-E that each form a part of the complete datastream being provided by the target data source 115. In some examples,the stream aggregator 630 receives the partial data streams from all ofthe secondary user devices 105B-E and aggregates the partial datastreams (e.g., possibly after reordering to account for different datapacket arrival times at the different user devices 105A-E) to form thecomplete data stream being provided by the target data source 115. Insome examples supporting hierarchical aggregation as described above,the stream aggregator 630 receives the partial data streams from asubset of one or more of the secondary user devices 105B-E andaggregates the partial data streams (e.g., possibly after reordering toaccount for different data packet arrival times at the different userdevices 105A-E) to form an intermediate aggregated data stream to beprovided to another user device, or any other device, that is toaggregate other intermediate aggregated data streams determined byother(s) of the devices 105A-E to form the complete data stream.

The example primary user device 105A of FIG. 4 also includes an examplestream relayer 635 to relay (e.g., via the local area transceiver 610)the complete aggregated data stream, or an intermediate aggregated datastream in the case of an example hierarchical aggregationimplementation, to a recipient. For example, the stream relayer 635 cancommunicate the complete data stream from the target data source 115,which is formed by the stream aggregator 630 through aggregating all ofthe partial data streams received by the primary user device 105A andthe secondary user devices 105B-E, to the output device 125 for furtherprocessing, presentation, etc. As another example, the stream relayer635 can communicate an intermediate aggregated data stream formed by thestream aggregator 630 through aggregating a subset of the partial datastreams received by the primary user device 105A and the secondary userdevices 105B-E to another of the user devices 105B-E for furtheraggregation.

In some examples, the primary user device 105A of FIG. 4 includes anexample shared connection controller 640 to monitor and/or otherwisecontrol the shared connection established in response to the sharedconnection request generated and sent by the shared connection requestor625. For example, the shared connection controller 640 can detect, viadata communications exchanged via the local area transceiver 610, one ormore secondary user devices, such as one or more of the secondarydevices 105B-E, entering or leaving an operating area, or otherwisebecoming available or unavailable. Additionally or alternatively, theshared connection controller 640 can interface with the primary deviceGUI 615 to enable a user to manually enter changes in the composition ofthe secondary devices 105B-E to be included in the shared connection viawhich communication of the data stream provided by the target datasource 115 is to be distributed. The shared connection controller 640can then report such changes in the composition of the secondary devices105B-E associated with the existing shared connection to enable thedistribution system 120 to modify the shared connection accordingly.

A block diagram depicting an example implementation of any one of thesecondary user devices 105B-E of FIG. 1 is illustrated in FIG. 5. Forconvenience and without loss of generality, the example block diagram ofFIG. 5 is described from the perspective of implementing the secondaryuser device 105B, but the example of FIG. 5 could additionally oralternatively be used to implement other ones of the secondary userdevices 105B-E. Turning to FIG. 5, the example secondary user device105B of the illustrated example includes an example wide areatransceiver 705 and an example local area transceiver 710, which may besimilar to the wide area transceiver 605 and the example local areatransceiver 610 included in the example primary user device 105A of FIG.4.

In the illustrated example of FIG. 5, the example secondary user device105B also includes an example secondary device GUI 715 to provide aninterface by which a user may cause the secondary user device 105B tojoin a shared connection being established by a primary user device,such as the primary user device 105A. For example, the secondary deviceGUI 715 can be implemented by an Internet browser, a WAP browser, a JAVAapplication, etc. In some examples, the secondary device GUI 715provides an interface to enable a user to cause the secondary userdevice 105B to announce (e.g., via data communications using the localarea transceiver 710) its availability for joining a group of userdevices, such as the group of devices 105A-E, to be included in a sharedconnection request. In some examples, the secondary device GUI 715additionally or alternatively provides an interface to enable a user toinitiate establishment (e.g., based on a received network address and/orsharing code, as described above) of a data connection with adistribution system, such as the distribution system 120, which is toreceive a partial data stream as part of a shared connection being usedto distribute a data stream among multiple user devices. Also, in someexamples, the secondary device GUI 715 enables a user to specify whetherlocation information for the secondary device 105B is to be included incommunications sent to the distribution system 120. In some examples,the secondary device GUI 715 additionally or alternatively provides aninterface to enable a user to update the availability of the secondaryuser device 105B for inclusion in an existing shared connection. In suchexamples, in response to receiving a status update via the secondarydevice GUI 715, the secondary user device 105B can send the statusupdate via the local area transceiver 710 to the primary user device105A for reporting via its shared connection controller 640.

The example secondary user device 105B of FIG. 5 further includes anexample shared connection establisher 720 to establish a data connectionwith a distribution system, such as the distribution system 120, tothereby join a shared connection being used to distribute communicationof a data stream among multiple devices. For example, the secondary userdevice 105B may receive a network address (e.g., an IP address, URI,etc.) and/or a sharing code from the primary user device 105A for use inestablishing a data connection with the distribution system 120 tothereby join a shared connection that was requested by the primary userdevice 105A for the purpose of distributing communication of a datastream from a target data source 115 among multiple devices, includingthe secondary user device 105B. In response to receiving such a networkaddress and/or sharing code, the shared connection establisher 720contacts the distribution system 120 (e.g., automatically or in responseto a user input received via the secondary device GUI 715) using thenetwork address and/or sharing code, which causes the distributionsystem 120 to establish a data connection with the secondary user device105B, and to also associate the data connection and/or the secondaryuser device 105B with the shared connection requested by the primaryuser device 105A.

The example secondary user device 105B of FIG. 5 also includes anexample stream aggregator 730 and an example stream relayer 735, whichmay be similar to the stream aggregator 630 and an example streamrelayer 635 included in the primary user device 105A of FIG. 4. Forexample, the stream relayer 735 may be used to relay or otherwisecommunicate a partial data stream received via the wide area transceiver705 of the secondary user device 105B, and associated with a target datastream being communicated by a shared connection, to the primary userdevice 105A or another of the secondary user devices 105C-E foraggregation to form the complete data stream. Additionally oralternatively, the stream aggregator 730 may be used to aggregate thepartial data stream received via the wide area transceiver 705 of thesecondary user device 105B with partial data streams from one or more ofthe user devices 105A, C-E to, for example, implement hierarchicalaggregation, as described above.

While example manners of implementing the example communication system100, the example user devices 105A-E, the example service providernetwork(s) 110, the example data source(s) 115, the example distributionsystem 120, the example output device 125, the example distributionserver 130, the example connection manager 135, the example datareceiver 405, the example stream splitter 410, the example transcoder415, the example shared connection request receiver 505, the exampleshared connection allocator 510, the example data stream initiator 515,the example shared connection monitor 520, the example wide areatransceiver 605, the example local area transceiver 610, the exampleprimary device GUI 615, the example secondary device identifier 620, theexample shared connection requestor 625, the example stream aggregator630, the example stream relayer 635, the example shared connectioncontroller 640, the example wide area transceiver 705, the example localare transceiver 710, the example secondary device GUI 715, the exampleshared connection establisher 720, the example stream aggregator 730 andthe example stream relayer 735 have been illustrated in FIGS. 1-5, oneor more of the elements, processes and/or devices illustrated in FIGS.1-5 may be combined, divided, re-arranged, omitted, eliminated and/orimplemented in any other way. Further, the example user devices 105A-E,the example service provider network(s) 110, the example data source(s)115, the example distribution system 120, the example output device 125,the example distribution server 130, the example connection manager 135,the example data receiver 405, the example stream splitter 410, theexample transcoder 415, the example shared connection request receiver505, the example shared connection allocator 510, the example datastream initiator 515, the example shared connection monitor 520, theexample wide area transceiver 605, the example local area transceiver610, the example primary device GUI 615, the example secondary deviceidentifier 620, the example shared connection requestor 625, the examplestream aggregator 630, the example stream relayer 635, the exampleshared connection controller 640, the example wide area transceiver 705,the example local are transceiver 710, the example secondary device GUI715, the example shared connection establisher 720, the example streamaggregator 730, the example stream relayer 735 and/or, more generally,the example communication system 100 of FIGS. 1-5 may be implemented byhardware, software, firmware and/or any combination of hardware,software and/or firmware. Thus, for example, any of the example userdevices 105A-E, the example service provider network(s) 110, the exampledata source(s) 115, the example distribution system 120, the exampleoutput device 125, the example distribution server 130, the exampleconnection manager 135, the example data receiver 405, the examplestream splitter 410, the example transcoder 415, the example sharedconnection request receiver 505, the example shared connection allocator510, the example data stream initiator 515, the example sharedconnection monitor 520, the example wide area transceiver 605, theexample local area transceiver 610, the example primary device GUI 615,the example secondary device identifier 620, the example sharedconnection requestor 625, the example stream aggregator 630, the examplestream relayer 635, the example shared connection controller 640, theexample wide area transceiver 705, the example local are transceiver710, the example secondary device GUI 715, the example shared connectionestablisher 720, the example stream aggregator 730, the example streamrelayer 735 and/or, more generally, the example communication system 100could be implemented by one or more circuit(s), programmableprocessor(s), application specific integrated circuit(s) (ASIC(s)),programmable logic device(s) (PLD(s)) and/or field programmable logicdevice(s) (FPLD(s)), etc. When any of the apparatus or system claims ofthis patent are read to cover a purely software and/or firmwareimplementation, at least one of the example communication system 100,the example user devices 105A-E, the example service provider network(s)110, the example data source(s) 115, the example distribution system120, the example output device 125, the example distribution server 130,the example connection manager 135, the example data receiver 405, theexample stream splitter 410, the example transcoder 415, the exampleshared connection request receiver 505, the example shared connectionallocator 510, the example data stream initiator 515, the example sharedconnection monitor 520, the example wide area transceiver 605, theexample local area transceiver 610, the example primary device GUI 615,the example secondary device identifier 620, the example sharedconnection requestor 625, the example stream aggregator 630, the examplestream relayer 635, the example shared connection controller 640, theexample wide area transceiver 705, the example local are transceiver710, the example secondary device GUI 715, the example shared connectionestablisher 720, the example stream aggregator 730 and/or the examplestream relayer 735 are hereby expressly defined to include a tangiblecomputer readable medium such as a memory, digital versatile disk (DVD),compact disk (CD), Blu-ray Disc™, etc., storing such software and/orfirmware. Further still, the examples of FIGS. 1-5 may include one ormore elements, processes and/or devices in addition to, or instead of,those illustrated in FIGS. 1-5, and/or may include more than one of anyor all of the illustrated elements, processes and devices.

Flowcharts representative of example machine readable instructions forimplementing the example communication system 100, the example userdevices 105A-E, the example service provider network(s) 110, the exampledata source(s) 115, the example distribution system 120, the exampleoutput device 125, the example distribution server 130, the exampleconnection manager 135, the example data receiver 405, the examplestream splitter 410, the example transcoder 415, the example sharedconnection request receiver 505, the example shared connection allocator510, the example data stream initiator 515, the example sharedconnection monitor 520, the example wide area transceiver 605, theexample local area transceiver 610, the example primary device GUI 615,the example secondary device identifier 620, the example sharedconnection requestor 625, the example stream aggregator 630, the examplestream relayer 635, the example shared connection controller 640, theexample wide area transceiver 705, the example local are transceiver710, the example secondary device GUI 715, the example shared connectionestablisher 720, the example stream aggregator 730 and/or the examplestream relayer 735 are shown in FIGS. 6-9. In these examples, themachine readable instructions represented by each flowchart may compriseone or more programs for execution by a processor, such as the processor1812 shown in the example processing system 1800 discussed below inconnection with FIG. 10. The one or more programs, or portion(s)thereof, may be embodied in software stored on a tangible computerreadable medium such as a CD-ROM, a floppy disk, a hard drive, a digitalversatile disk (DVD), a Blu-ray Disc™, or a memory associated with theprocessor 1812, but the entire program or programs and/or portionsthereof could alternatively be executed by a device other than theprocessor 1812 (e.g., such as a controller and/or any other suitabledevice) and/or embodied in firmware or dedicated hardware (e.g.,implemented by an ASIC, a PLD, an FPLD, discrete logic, etc.). Also, oneor more of the machine readable instructions represented by theflowchart of FIGS. 6-9 may be implemented manually. Further, althoughthe example machine readable instructions are described with referenceto the flowcharts illustrated in FIGS. 6-9, many other methods ofimplementing the example communication system 100, the example userdevices 105A-E, the example service provider network(s) 110, the exampledata source(s) 115, the example distribution system 120, the exampleoutput device 125, the example distribution server 130, the exampleconnection manager 135, the example data receiver 405, the examplestream splitter 410, the example transcoder 415, the example sharedconnection request receiver 505, the example shared connection allocator510, the example data stream initiator 515, the example sharedconnection monitor 520, the example wide area transceiver 605, theexample local area transceiver 610, the example primary device GUI 615,the example secondary device identifier 620, the example sharedconnection requestor 625, the example stream aggregator 630, the examplestream relayer 635, the example shared connection controller 640, theexample wide area transceiver 705, the example local are transceiver710, the example secondary device GUI 715, the example shared connectionestablisher 720, the example stream aggregator 730 and/or the examplestream relayer 735 may alternatively be used. For example, withreference to the flowcharts illustrated in FIGS. 6-9, the order ofexecution of the blocks may be changed, and/or some of the blocksdescribed may be changed, eliminated, combined and/or subdivided intomultiple blocks.

As mentioned above, the example processes of FIGS. 6-9 may beimplemented using coded instructions (e.g., computer readableinstructions) stored on a tangible computer readable medium such as ahard disk drive, a flash memory, a read-only memory (ROM), a CD, a DVD,a cache, a random-access memory (RAM) and/or any other storage media inwhich information is stored for any duration (e.g., for extended timeperiods, permanently, brief instances, for temporarily buffering, and/orfor caching of the information). As used herein, the term tangiblecomputer readable medium is expressly defined to include any type ofcomputer readable storage and to exclude propagating signals.Additionally or alternatively, the example processes of FIGS. 6-9 may beimplemented using coded instructions (e.g., computer readableinstructions) stored on a non-transitory computer readable medium, suchas a flash memory, a ROM, a CD, a DVD, a cache, a random-access memory(RAM) and/or any other storage media in which information is stored forany duration (e.g., for extended time periods, permanently, briefinstances, for temporarily buffering, and/or for caching of theinformation). As used herein, the term non-transitory computer readablemedium is expressly defined to include any type of computer readablemedium and to exclude propagating signals. Also, as used herein, theterms “computer readable” and “machine readable” are consideredequivalent unless indicated otherwise. Furthermore, as used herein, whenthe phrase “at least” is used as the transition term in a preamble of aclaim, it is open-ended in the same manner as the term “comprising” isopen ended. Thus, a claim using “at least” as the transition term in itspreamble may include elements in addition to those expressly recited inthe claim.

Example machine readable instructions 1300 that may be executed toimplement the example communication system 100 of FIG. 1 are representedby the flowchart shown in FIG. 6. With reference to the precedingfigures and associated descriptions, the machine readable instructions1300 of FIG. 6 begin execution at block 1302 at which the user devices105A-E are linked via, for example, an ad-hoc network, tetheringconnections and/or other communication links, as described above. Atblock 1304, the primary user device 105A initiates a shared connectionrequest to the distribution system 120, as described above. In theillustrated example of FIG. 6, the shared connection request includesinformation identifying a number of secondary user devices 105B-E to beincluded in the shared connection being requested. The shared connectionrequest initiated at block 1304 also includes information identifyingthe target data (e.g., the target data source 115) that is to providethe data stream whose communication is to be distributed among the userdevices 105A-E identified by the shared connection request.

At block 1308, the distribution system 120 receives the sharedconnection request from the primary user device 105A and uses the numberof secondary devices indicated in the request to determine a number ofnetwork addresses to be provided to the secondary devices 105B-E for usein establishing data connections with the distribution system 120, asdescribed above. In some examples, at block 1308 the distribution system120 additionally or alternatively determines a sharing code to be usedto associate user devices with the shared connection being requested, asdescribed above. At block 1308, the distribution system 120 provides thenetwork addresses and/or the sharing code to the primary user device105A.

At block 1312, the primary user device 105A receives the networkaddresses and/or the sharing code provided by the distribution system120 in response to the shared connection request initiated at block1304. As described above, the primary user device 105A distributes thereceived network addresses and/or sharing code to the secondary userdevices 105B-E via the local communication links established at block1302. At block 1316, the secondary user devices 105B-E use the networkaddresses and/or sharing code received from the primary user device 105Ato contact the distribution system 120 to thereby establish respectivedata connections (e.g., secondary data connections) with the userdevices 105B-E, as described above, via which communication of a datastream is be distributed. At block 1320, the distribution system 120determines device capability information for the user devices 105A-E tobe included in the requested shared connection. For example, and asdescribed above, the distribution system 120 may exchange communicationmessages, such a network ping messages, with the user devices 105A-E todetermine respective device capability information, such as bandwidthand/or data rate capabilities, network latencies, etc., for the userdevices 105A-E.

At block 1322, the distribution system 120 associates data transmissioncharacteristics with the data connections to complete establishment ofthe data connections with the user devices 105A-E. As described above,the data transmission characteristics determined for the respective dataconnections are based on the device capability information obtained forthe respective user devices 105A-E, thereby causing each dataconnections to be tailored to its respective user device 105A-E. Asdescribed above, the data connections established with the user devices105A-E are used to convey the partial data streams associated with acomplete data stream to the user devices 105A-E.

At block 1324, the distribution system 120 initiates the transfer of thedata stream from the target data source 115 identified in the sharedconnection request, and splits the complete data stream into partialdata streams to be communicated to the user devices 105A-E via theestablished data connections, as described above. At block 1326, theuser devices 105A-E receive their respective partial data streams viatheir respective data connections with the distribution system 120. Atblock 1328, the partial data streams are aggregated, as described above,to form the complete data stream being provided by the target datasource 115. At block 1330, the complete data stream formed byaggregating the partial data streams is output to, for example, theoutput device 125 and/or processed by one of the user devices, such asthe primary user device 105A.

Example machine readable instructions 1400 that may be executed toimplement the example primary user device 105A of FIGS. 1 and/or 4 arerepresented by the flowchart shown in FIG. 7. For convenience, andwithout loss of generality, execution of the machine readableinstructions 1400 is described in the context of the primary user device105A operating in the example communication system 100 of FIG. 1.Turning to FIG. 7, and with reference to the preceding figures andassociated descriptions, the machine readable instructions 1400 beginexecution at block 1402 at which the secondary device identifier 620 ofthe primary user device 105A identifies the secondary user devices105B-E to be included in a shared connection for distributingcommunication of a data stream from a target data source 115. Forexample, at block 1402, the primary user device 105A can use anauto-discovery procedure, information entered via the primary device GUI615, etc., to identify the secondary user devices 105B-E, as describedabove. At block 1403, the primary user device 105A uses its local areatransceiver 610 to establish local communication links, such astethering links, an ad-hoc network, etc., with the secondary userdevices 105B-E identified at block 1402.

At block 1404, the shared connection requestor 625 of the primary userdevice 105A generates and sends a shared connection request to thedistribution system 120 to request a shared connection for distributingcommunication of a data stream being provided by an identified targetdata source 115. In the illustrated example of FIG. 7, the sharedconnection request includes information identifying the number ofsecondary user devices 105B-E to be included in the shared connectionbeing requested. The shared connection request initiated at block 1015also includes information identifying the target data (e.g., the targetdata source 115) that is to provide the data stream whose communicationis to be distributed among the user devices 105A-E.

At block 1408, the shared connection requestor 625 receives one or morenetwork addresses and/or a sharing code from the distribution system 120in response to the shared connection request initiated at block 1404, asdescribed above. At block 1412, the shared connection requestor 625distributes (e.g., via the local communication links established atblock 1010) the network addresses and/or the sharing code to thesecondary user devices 105B-E to be included in the shared connection,as described above. For example, the number of network addressesreceived at block 1408 may correspond to the number of secondary userdevices 105B-E indicated in the shared connection request. In suchexamples, the shared connection requestor 625 of the primary user device105A may forward a different network address to each respectivesecondary user device 105B-E. As noted above, the network addressesand/or sharing code distributed to the secondary user devices 105B-E areused by the secondary user device 105B-E to establish respective dataconnections with the distribution system 120.

At block 1420, the primary user device 105A receives an indication fromthe distribution system 120 (e.g., via a message received from theservice provider network 110 by the wide area transceiver 605 of theprimary user device 105A) indicating that the requested sharedconnection has been established. For example, the distribution system120 may send such an indication to the primary user device 105A afterthe data connections have been established (e.g., based on the deviceidentification information included in the request) with all of the userdevices 105A-E that are to be included in the shared connection. Afterthe shared connection is established, at block 1425, the primary userdevice 105A begins receiving, via its wide area transceiver 605, apartial data stream corresponding to a portion of the complete datastream being provided by the target data source 115 identified in theshared connection request.

At block 1430, the stream aggregator 630 of the primary user device 105Areceives, via the local communication links established at block 1403,the partial data streams received by the other (e.g., secondary) userdevices 105B-E included in the shared connection. At block 1435, thestream aggregator 630 aggregates, as described above, the partial datastreams (e.g., possibly after reordering to account for different datapacket arrival times at the different user devices 105A-E) to form thecomplete data stream being provided by the target data source 115. Atblock 1440, the primary user device 105A performs any appropriatepost-processing on the aggregated, complete data stream, and/or thestream relayer 635 of the primary user device 105A outputs the completedata stream for use by another device, such as the output device 125.

If the transfer of the data stream is not complete and, thus, the datastream is still being communicated (block 1445), then at block 1450, theshared connection controller 640 of the primary user device 105Amonitors the status of the shared connection, as described above. Forexample, the shared connection controller 640 can detect changes in thecomposition (e.g., membership) of the group of user devices 105A-E(e.g., such as when device(s) enter and/or leave an operating area)automatically (e.g., via communications exchanged using the local areatransceiver 610) and/or manually (e.g., via information entered via theprimary device GUI 615). At block 1455, the shared connection controller640 sends (e.g., via its wide area transceiver 605) any status updatesto the distribution system 120. Processing then returns to block 1425and blocks subsequent thereto at which the primary user device 105Acontinues to receive its partial data stream corresponding to a portionof the complete data stream being provided by the target data source 115(although the data transmission characteristic(s) of the partial datastream may be modified by the distribution system 120 in response tostatus update(s) received via the processing at block 1455).

Example machine readable instructions 1500 that may be executed toimplement one or more of the example secondary user devices 105B-E ofFIGS. 1 and/or 5 are represented by the flowchart shown in FIG. 8. Forconvenience, and without loss of generality, execution of the machinereadable instructions 1500 is described in the context of the secondaryuser device 105B operating in the example communication system 100 ofFIG. 1. Turning to FIG. 8, and with reference to the preceding figuresand associated descriptions, the machine readable instructions 1500begin execution at block 1504 at which the secondary user device 105Buses its local area transceiver 710 to establish a local communicationlink with a primary device, such as the primary user device 105A, asdescribed above. At block 1508, the shared connection establisher 720 ofthe secondary user device 105B receives a network address and/or asharing code from the primary user device 105A for use in establishing adata connection with the distribution system 120, as described above. Atblock 1512, the shared connection establisher 720 establishes the dataconnection with the distribution system 120 using the received networkaddress and/or sharing code, as described above.

At block 1515, the secondary user device 105B begins receiving, via itswide area transceiver 705, a partial data stream corresponding to aportion of the complete data stream being provided by a target datasource 115 (e.g., which is the subject of the shared connection in whichthe secondary user device 105B has joined). In some examples, such asexamples supporting hierarchical aggregation, at block 1520, the streamaggregator 730 of the secondary user device 105B receives, via localcommunication links established using its local area transceiver 710,the partial data stream(s) received by one or more of the other userdevices 105A, C-E included in the shared connection. At block 1525, thestream aggregator 730 aggregates, as described above, the partial datastreams (e.g., possibly after reordering to account for different datapacket arrival times at the different user devices 105A-E) to form, forexample, an intermediate aggregated data stream corresponding to aportion of the complete data stream being provided by the target datasource 115. At block 1530, the stream relayer 735 of the secondary userdevice 105B outputs the intermediate aggregated data stream for use byanother device, such as the primary user device 105A, to complete thehierarchical aggregation process. If the transfer of the data stream isnot complete and, thus, the data stream is still being communicated(block 1535), then processing then returns to block 1515 and blockssubsequent thereto at which the secondary user device 105B continues toreceive its partial data stream corresponding to its portion of thecomplete data stream being provided by the target data source 115(although the data transmission characteristic(s) of the partial datastream may be modified by the distribution system 120 in response tochanges in the status of the shared connection, as described above).

Example machine readable instructions 1600 that may be executed toimplement the example distribution system 120 and, more particularly,the example distribution server 130 and/or the example connectionmanager 135 of FIGS. 1-3 are represented by the flowchart shown in FIG.9. For convenience, and without loss of generality, execution of themachine readable instructions 1600 is described in the context of thedistribution server 130 and the connection manager 135 operating in theexample communication system 100 of FIG. 1. Turning to FIG. 9, and withreference to the preceding figures and associated descriptions, themachine readable instructions 1600 begin execution at block 1602 atwhich the shared connection request receiver 505 of the connectionmanager 135 receives a shared connection request from the primary userdevice 105A, as described above. In the illustrated example, the sharedconnection request includes information identifying the number ofsecondary devices 105B-E to be included in the shared connection. Insome examples, the shared connection request may count the primary userdevice 105A in a total number of user devices 105A-E indicated in theshared connection request, or the primary user device 105A may beimplicitly assumed to be included in the shared connection and, thus,not included in the number of user devices 105B-E indicated in therequest. In the illustrated example, the shared connection requestreceived at block 1602 also includes data source identificationinformation identifying a target data source 115 that is to provide adata stream whose communication is to be distributed using the requestedshared connection.

At block 1604, the shared connection allocator 510 provides one or morenetwork addresses and/or a sharing code to the primary user device 105Ain response to the received shared connection request. For example, anda described above, the shared connection allocator 510 may provide anumber of network addresses corresponding to the number of secondaryuser devices 105B-E indicated in the shared connection request, whereeach network address is associated with a respective data connection tobe established with one of the secondary user devices 105B-E. In someexamples, the shared connection allocator 510 provides the sharing codein addition or as an alternative to the network addresses, where thesharing code is to be used by the user devices 105A-E to indicate thatthey belong to a particular, requested shared connection. At block 1606,the shared connection allocator 510 receives connection requests fromthe secondary user devices 105B-E at the provided network address(es)and/or including the provided sharing code, and establishes respectivedata connections with the secondary user devices 105B-E in response toreceiving the requests, as described above. At block 1608, the sharedconnection allocator 510 actively determines device capabilityinformation for the user devices 105A-E to be included in the requestedshared connection by, for example, exchanging communication messages,such a network ping messages, with each user device 105A-E todetermine/measure device capability information, such as bandwidthand/or data rate capabilities, network latencies, etc.

At block 1615, the shared connection allocator 510 establishesrespective data connections with the user devices 105A-E by associatedrespective data transmission capabilities with the initial dataconnection established with the user devices 105A-E by the serviceprovider network 110, as described above. For example, the datatransmission capabilities to be associated with each data connection canbe determined by the shared connection allocator 510 using the devicecapability information obtained for the particular user deviceassociated with the data connection, as further described above.

At block 1620, the connection manager 135 sends an indication to theprimary user device 105A that the shared connection has been establishedin response to the request received at block 1602. At block 1625, thedata stream initiator 515 of the connection manager 135 initiatestransfer of a data stream from the target data source 115 using thesource identification information included in the request received atblock 1602. At block 1630, the data receiver 405 of the distributionserver 130 receives the data stream from the target data source 115, andthe stream splitter 410 of the distribution server 130 splits theincoming data stream into partial data streams according to the datatransmission characteristics associated with the respective dataconnections established with the user devices 105A-E, as describedabove. In some examples, at block 1630, the transcoder 415 of thedistribution server 130 may be invoked to perform transcoding of thepartial data streams to conform them to the capabilities of the userdevices 105A-E. At block 1635, the stream splitter 410 sends the partialdata streams to the user devices 105A-E using the established dataconnections, as described above.

If the transfer of the data stream is not complete and, thus, the datastream is still being received and split by the distribution server 130(block 1640), then at block 1645, the shared connection monitor 520 ofthe connection manager 135 monitors the status of the shared connection,as described above. At block 1650, the shared connection allocator 510updates the shared connection characteristics, as appropriate, inresponse to any detected changes in the status of the shared connection.For example, the shared connection allocator 510 may cause removal ofthe data connection(s) for any user device(s) 105A-E that are no longeravailable, establishment of new data connection(s) for new userdevice(s) that become available, modification of data transmissioncharacteristics associated with one or more of the established dataconnections based on detection of changes to the device capability, linkstatus, etc., and/or any other appropriate change to the sharedconnection. Processing then returns to block 1630 and blocks subsequentthereto at which the distribution server 120 continues to receive theincoming data stream and to split it into its component partial datastreams for sending to the user devices 105A-E (although the datatransmission characteristic(s) of the partial data stream may bemodified in response to status update(s) received via the processing atblock 1650).

FIG. 10 is a block diagram of an example processing system 1800 capableof executing the instructions of FIGS. 6-9 to implement the examplecommunication system 100, the example user devices 105A-E, the exampleservice provider network(s) 110, the example data source(s) 115, theexample distribution system 120, the example output device 125, theexample distribution server 130, the example connection manager 135, theexample data receiver 405, the example stream splitter 410, the exampletranscoder 415, the example shared connection request receiver 505, theexample shared connection allocator 510, the example data streaminitiator 515, the example shared connection monitor 520, the examplewide area transceiver 605, the example local area transceiver 610, theexample primary device GUI 615, the example secondary device identifier620, the example shared connection requestor 625, the example streamaggregator 630, the example stream relayer 635, the example sharedconnection controller 640, the example wide area transceiver 705, theexample local are transceiver 710, the example secondary device GUI 715,the example shared connection establisher 720, the example streamaggregator 730 and/or the example stream relayer 735 of FIGS. 1-5. Theprocessing system 1800 can be, for example, a server, a personalcomputer, a mobile phone (e.g., a smartphone, a cell phone, etc.), apersonal digital assistant (PDA), an Internet appliance, a DVD player, aCD player, a digital video recorder, a Blu-ray player, a gaming console,a personal video recorder, a set top box, a digital camera, or any othertype of computing device.

The system 1800 of the instant example includes a processor 1812. Forexample, the processor 1812 can be implemented by one or moremicroprocessors and/or controllers from any desired family ormanufacturer.

The processor 1812 includes a local memory 1813 (e.g., a cache) and isin communication with a main memory including a volatile memory 1814 anda non-volatile memory 1816 via a bus 1818. The volatile memory 1814 maybe implemented by Static Random Access Memory (SRAM), SynchronousDynamic Random Access Memory (SDRAM), Dynamic Random Access Memory(DRAM), RAMBUS Dynamic Random Access Memory (RDRAM) and/or any othertype of random access memory device. The non-volatile memory 1816 may beimplemented by flash memory and/or any other desired type of memorydevice. Access to the main memory 1814, 1816 is controlled by a memorycontroller.

The processing system 1800 also includes an interface circuit 1820. Theinterface circuit 1820 may be implemented by any type of interfacestandard, such as an Ethernet interface, a universal serial bus (USB),and/or a PCI express interface.

One or more input devices 1822 are connected to the interface circuit1820. The input device(s) 1822 permit a user to enter data and commandsinto the processor 1812. The input device(s) can be implemented by, forexample, a keyboard, a mouse, a touchscreen, a track-pad, a trackball, atrackbar (such as an isopoint), a voice recognition system and/or anyother human-machine interface.

One or more output devices 1824 are also connected to the interfacecircuit 1820. The output devices 1824 can be implemented, for example,by display devices (e.g., a liquid crystal display, a cathode ray tubedisplay (CRT)), a printer and/or speakers. The interface circuit 1820,thus, typically includes a graphics driver card.

The interface circuit 1820 also includes a communication device, such asa modem or network interface card, to facilitate exchange of data withexternal computers via a network 1826 (e.g., an Ethernet connection, adigital subscriber line (DSL), a telephone line, coaxial cable, acellular telephone system, etc.).

The processing system 1800 also includes one or more mass storagedevices 1828 for storing machine readable instructions and data.Examples of such mass storage devices 1828 include floppy disk drives,hard drive disks, compact disk drives and digital versatile disk (DVD)drives.

Coded instructions 1832 corresponding to the instructions of FIGS. 6-9may be stored in the mass storage device 1828, in the volatile memory1814, in the non-volatile memory 1816, in the local memory 1813 and/oron a removable storage medium, such as a CD or DVD 1836.

At least some of the above described example methods and/or apparatusare implemented by one or more software and/or firmware programs runningon a computer processor. However, dedicated hardware implementationsincluding, but not limited to, application specific integrated circuits,programmable logic arrays and other hardware devices can likewise beconstructed to implement some or all of the example methods and/orapparatus described herein, either in whole or in part. Furthermore,alternative software implementations including, but not limited to,distributed processing or component/object distributed processing,parallel processing, or virtual machine processing can also beconstructed to implement the example methods and/or apparatus describedherein.

To the extent the above specification describes example components andfunctions with reference to particular standards and protocols, it isunderstood that the scope of this patent is not limited to suchstandards and protocols. For instance, each of the standards forInternet and other packet switched network transmission (e.g.,Transmission Control Protocol (TCP)/Internet Protocol (IP), UserDatagram Protocol (UDP)/IP, HyperText Markup Language (HTML), HyperTextTransfer Protocol (HTTP)) represent examples of the current state of theart. Such standards are periodically superseded by faster or moreefficient equivalents having the same general functionality.Accordingly, replacement standards and protocols having the samefunctions are equivalents which are contemplated by this patent and areintended to be included within the scope of the accompanying claims.

Additionally, although this patent discloses example systems includingsoftware or firmware executed on hardware, it should be noted that suchsystems are merely illustrative and should not be considered aslimiting. For example, it is contemplated that any or all of thesehardware and software components could be embodied exclusively inhardware, exclusively in software, exclusively in firmware or in somecombination of hardware, firmware and/or software. Accordingly, whilethe above specification described example systems, methods and articlesof manufacture, the examples are not the only way to implement suchsystems, methods and articles of manufacture. Therefore, althoughcertain example methods, apparatus and articles of manufacture have beendescribed herein, the scope of coverage of this patent is not limitedthereto. On the contrary, this patent covers all methods, apparatus andarticles of manufacture fairly falling within the scope of the claimseither literally or under the doctrine of equivalents.

What is claimed is:
 1. A method to distribute communication of acomplete data stream among multiple devices including a first device anda second device, the method comprising: receiving a sharing code at thefirst device from the second device, the sharing code being a samealphanumeric code to be provided by the second device to respectiveother ones of the multiple devices to identify the multiple devices asassociated with a shared connection to be established to distribute thecommunication of the complete data stream among the multiple devices;transmitting, by executing an instruction with a processor of the firstdevice, a request including the sharing code from the first device to adistribution system different from the second device, the distributionsystem to provide respective portions of the complete data stream to thefirst device and the second device, the request being to establish adata connection via which the first device is to receive a first partialdata stream corresponding to a first portion of the complete data streamfrom the distribution system; and forwarding, by executing aninstruction with the processor of the first device, the first partialdata stream from the first device to the second device.
 2. The method ofclaim 1, wherein the sharing code is assigned by the distribution systemto identify the multiple devices associated with the shared connection.3. The method of claim 1, further including: establishing, with a firsttransceiver of the first device, a communication link between the firstdevice and the second device, the first device to receive the sharingcode from the second device and forward the first partial data stream tothe second device via the first communication link; and establishing,with a second transceiver of the first device, the data connection viawhich the first device is to receive the first partial data stream fromthe distribution system, the second transceiver being different from thefirst transceiver.
 4. The method of claim 1, further includingreceiving, at the first device, a network address of the distributionsystem from the second device, and wherein the transmitting of therequest from the first device to the distribution system includestransmitting the request from the first device to the network address ofthe distribution system.
 5. The method of claim 4, wherein the networkaddress is a first network address of the distribution system, and thefirst network address is different from a second network address of thedistribution system provided by the second device to another one of themultiple devices different from the first device.
 6. The method of claim1, further including implementing, at the first device, a graphical userinterface to accept a user input indicating whether the first device isavailable for inclusion in the shared connection.
 7. The method of claim1, wherein the first device corresponds to a first mobile device, thesecond device corresponds to a second mobile device, and the multipledevices associated with the shared connection include the first mobiledevice and the second mobile device.
 8. A non-transitory computerreadable medium including computer readable instructions which, whenexecuted, cause a processor of a first device to perform operationscomprising: accessing a sharing code received from a second device, thesharing code being a same alphanumeric code to be provided by the seconddevice to respective other ones of multiple devices to identify themultiple devices as associated with a shared connection to beestablished to distribute communication of a complete data stream amongthe multiple devices, the multiple devices including the first deviceand the second device; transmitting a request including the sharing codefrom the first device to a distribution system different from the seconddevice, the distribution system to provide respective portions of thecomplete data stream to the first device and the second device, therequest being to establish a data connection via which the first deviceis to receive a first partial data stream corresponding to a firstportion of the complete data stream from the distribution system; andforwarding the first partial data stream from the first device to thesecond device.
 9. The non-transitory computer readable medium of claim8, wherein the sharing code is assigned by the distribution system toidentify the multiple devices associated with the shared connection. 10.The non-transitory computer readable medium of claim 8, wherein theoperations further include: establishing, with a first transceiver ofthe first device, a communication link between the first device and thesecond device, the first device to receive the sharing code from thesecond device and forward the first partial data stream to the seconddevice via the first communication link; and establishing, with a secondtransceiver of the first device, the data connection via which the firstdevice is to receive the first partial data stream from the distributionsystem, the second transceiver being different from the firsttransceiver.
 11. The non-transitory computer readable medium of claim 8,wherein the operations further include receiving a network address ofthe distribution system from the second device, and wherein thetransmitting of the request from the first device to the distributionsystem includes transmitting the request from the first device to thenetwork address of the distribution system.
 12. The non-transitorycomputer readable medium of claim 11, wherein the network address is afirst network address of the distribution system, and the first networkaddress is different from a second network address of the distributionsystem provided by the second device to another one of the multipledevices different from the first device.
 13. The non-transitory computerreadable medium of claim 8, wherein the operations further includeimplementing a graphical user interface to accept a user inputindicating whether the first device is available for inclusion in theshared connection.
 14. The non-transitory computer readable medium ofclaim 8, wherein the first device corresponds to a first mobile device,the second device corresponds to a second mobile device, and themultiple devices associated with the shared connection include the firstmobile device and the second mobile device.
 15. A first devicecomprising: memory including computer readable instructions; and aprocessor responsive to the computer readable instructions to performoperations including: accessing a sharing code received from a seconddevice, the sharing code being a same alphanumeric code to be providedby the second device to respective other ones of multiple devices toidentify the multiple devices as associated with a shared connection tobe established to distribute communication of a complete data streamamong the multiple devices, the multiple devices including the firstdevice, and the second device; transmitting a request including thesharing code from the first device to a distribution system differentfrom the second device, the distribution system to provide respectiveportions of the complete data stream to the first device and the seconddevice, the request being to establish a data connection via which thefirst device is to receive a first partial data stream corresponding toa first portion of the complete data stream from the distributionsystem; and forwarding the first partial data stream from the firstdevice to the second device.
 16. The first device of claim 15, whereinthe sharing code is assigned by the distribution system to identify themultiple devices associated with the shared connection.
 17. The firstdevice of claim 15, further including: a first transceiver; and a secondtransceiver different from the first transceiver, and the operationsfurther include (1) establishing, with the first transceiver, acommunication link between the first device and the second device, thefirst device to receive the sharing code from the second device andforward the first partial data stream to the second device via the firstcommunication link, and (2) establishing, with the second transceiver,the data connection via which the first device is to receive the firstpartial data stream from the distribution system.
 18. The first deviceof claim 15, wherein the operations further include receiving a networkaddress of the distribution system from the second device, and whereinthe transmitting of the request from the first device to thedistribution system includes transmitting the request from the firstdevice to the network address of the distribution system.
 19. The firstdevice of claim 18, wherein the network address is a first networkaddress of the distribution system, and the first network address isdifferent from a second network address of the distribution systemprovided by the second device to another one of the multiple devicesdifferent from the first device.
 20. The first device of claim 15,wherein the operations further include implementing a graphical userinterface to accept a user input indicating whether the first device isavailable for inclusion in the shared connection.